CN115682101A - Low-carbon environment-friendly intelligent household equipment - Google Patents

Abstract

The invention discloses low-carbon environment-friendly intelligent household equipment, which relates to the technical field of intelligent household and comprises a heat-insulating energy-storing component, an air-conditioning system, a partition arranged in a house, a solar photovoltaic component arranged outside the house and a communication control component arranged outside the house, wherein a heat-insulating door is arranged on the side surface of the partition, and a ventilating window and a temperature-adjusting window are respectively arranged on two sides of the top surface of the partition.

Description

Low-carbon environment-friendly intelligent household equipment

Technical Field

The invention relates to the technical field of intelligent home, in particular to low-carbon environment-friendly intelligent home equipment.

Background

Compared with the common home, the intelligent home has the traditional living function, has the functions of building, network communication, information appliance automation and equipment automation, provides an all-round information interaction function, and even saves funds for various energy expenses.

Homes such as a walking-up bed, a shelf bed and a partition wall are widely used by a plurality of families, but the general sealing and heat-insulating effects of the homes are poor, the homes are caused to be hot in summer and cold in winter, the high-power household appliances are required to be utilized for temperature adjustment by means of municipal power supply, the power consumption is large, the energy consumption is high, the carbon emission is high, and the parts in the existing part of intelligent homes cannot be automatically cleaned and maintained, so that the normal work of the intelligent homes is influenced.

Disclosure of Invention

The invention aims to overcome the defects in the prior art, provides the low-carbon environment-friendly intelligent household equipment, saves energy, reduces carbon emission, has a good low-carbon environment-friendly effect, and can effectively solve the problems in the background art.

In order to achieve the purpose, the invention provides the following technical scheme: a low-carbon environment-friendly intelligent household device comprises a heat-insulation energy-storage assembly, an air-conditioning system, a partition wall arranged in a house, a solar photovoltaic assembly arranged outside the house and a communication control assembly arranged outside the house, wherein a heat-insulation door is arranged on the side surface of the partition wall, and a ventilation window and a temperature-adjusting window are respectively arranged on two sides of the top surface of the partition wall;

an insulating layer is arranged between the inner wall and the outer wall of the partition, and a haze-proof filter element is embedded in the ventilation window;

the inner side of the partition is provided with a heat recovery assembly, and the heat recovery assembly is matched with the heat insulation layer and the heat insulation energy storage assembly to realize self-heating of the partition in winter.

Preferably, the communication control assembly comprises a municipal power supply module, a single-chip microcomputer controller, a climate monitoring module and a wireless communication module, the municipal power supply module is arranged on the outer side of the house, the output end of the municipal power supply module is electrically connected with the input end of the single-chip microcomputer controller, the single-chip microcomputer controller is electrically connected with the wireless communication module in a two-way mode, the output end of the single-chip microcomputer controller is electrically connected with the input end of the air conditioning system, and the climate monitoring module is electrically connected with the single-chip microcomputer controller in a two-way mode.

Preferably, solar PV modules is including locating frame plate, charge controller and the dc-to-ac converter in the house outside, the tip of frame plate is equipped with branch, the top of branch is equipped with the installing frame, the inside of installing frame is provided with the solar PV board, the surface of frame plate is equipped with the battery, the output of solar PV board with charge controller's input electricity is connected, charge controller's output with the input electricity of battery is connected, the output of battery with the input electricity of dc-to-ac converter is connected, the output of dc-to-ac converter with single chip microcomputer controller's input electricity is connected.

Preferably, the heat recovery assembly comprises a radiator arranged on the inner wall of the partition, and the air conditioning system comprises an air conditioner internal unit arranged on the inner wall of the partition and an air conditioner external unit arranged on the outer side of the house.

Preferably, the heat preservation energy storage assembly comprises a heat preservation box arranged outside the house, a return pipe is arranged on the top surface of the heat preservation box and communicated with an output pipe of the radiator, a water pump is arranged on the top surface of the heat preservation box, an input port of the water pump is communicated with the heat preservation box, an output port of the water pump is communicated with an input pipe of the radiator through a guide pipe, and an input end of the water pump is electrically connected with an output end of the single chip microcomputer controller.

Preferably, the radiator is last to have cup jointed back the shape seat, the inside cavity of having seted up in both sides of returning the shape seat, the upside of cavity is equipped with the baffle, the mesopore has been seted up at the middle part of baffle, be located in the cavity the both ends of baffle upside all are equipped with the baffle, the haulage rope has been run through at the middle part of baffle, the haulage rope is kept away from mesoporous one end and is run through the top of cavity and the top fixed connection of radiator, the middle part of baffle is located mesoporous bilateral symmetry sliding fit has the piston plate, the other end of haulage rope with the middle part fixed connection of piston plate, the position that lies in on the haulage rope between baffle and the piston plate has cup jointed the spring, the exhaust hole has been seted up with the position that the piston plate corresponds to the tip of returning the shape seat.

Preferably, the top dorsal part of radiator is equipped with the return bend, the bottom of return bend is connected with the bellows, the bottom of bellows and the top surface fixed connection who returns the shape seat, be equipped with the solenoid valve on the return bend, the bottom correspondence of two relative medial surfaces of returning the shape seat sets up the logical groove with the cavity intercommunication, it has the slide, two to lead to sliding fit in the groove the opposite flank of slide all is equipped with the clutch blocks, the side of slide evenly runs through has seted up the suction hole, one side that the slide is located the cavity is equipped with the rubber bag with cavity inner wall fixed connection, the top correspondence of two relative medial surfaces of returning the shape seat is equipped with the cleaning brush, the inner wall that cuts off is equipped with the vision sensor with the position that the dorsal part of radiator corresponds, vision sensor and single chip microcomputer controller both-way electricity are connected.

Preferably, a water injection pipe is arranged on the top surface of the heat preservation box, a second temperature sensor is arranged on the side surface of the heat preservation box, an electric heater is arranged on the top surface of the heat preservation box, the output end of the single chip microcomputer controller is electrically connected with the input end of the electric heater, and the single chip microcomputer controller is electrically connected with the second temperature sensor in a bidirectional mode.

Preferably, a first temperature sensor is arranged on the inner side of the partition and is electrically connected with the single chip microcomputer controller in a bidirectional mode.

Preferably, the heat-insulating layer is made of rubber-plastic foam boards, polyurethane, extrusion molding core boards, PVC, STP and VIP heat-insulating materials.

Compared with the prior art, the invention has the following advantages:

1. this low carbon environment-friendly intelligent household equipment can utilize the better thermal-insulated effect of heat preservation in summer, effectively reduces the entering of cutting off outside heat and humid air, and then effectively reduces air conditioner load to effectively reduce the power consumption, further reduced the carbon and discharged.

2. This low carbon environment-friendly intelligent household equipment can utilize the better thermal-insulated effect of heat preservation winter, effectively reduces to cut off the outside microthermal entering of wall, realizes the recovery and the reuse to the human heat simultaneously, realizes winter self-heating, has reduced the carbon emission then.

3. The invention can remove dust impurities and stains with strong adhesiveness on the outer side of the radiator, prevent the dust impurities and the stains from influencing the heat exchange between the antifreeze in the radiator and the inner part of the partition, effectively slow down the further oxidation corrosion on the outer side of the radiator by removing the rust adhered on the outer side of the radiator, and prolong the service life.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of the structure of the incubator of the present invention;

FIG. 3 is a schematic view of the partition structure of the present invention;

FIG. 4 is a schematic view of a partition cross-sectional structure according to the present invention;

FIG. 5 is a schematic view of a heat sink according to the present invention;

FIG. 6 is a cross-sectional view of a heat sink according to the present invention;

FIG. 7 is a schematic cross-sectional view of a cavity according to the present invention;

FIG. 8 is a schematic top view of the clip seat of the present invention.

In the figure: 1. a wireless communication module; 2. separating; 201. a heat-insulating door; 202. a ventilation window; 203. a temperature adjusting window; 204. a first temperature sensor; 205. a heat-insulating layer; 206. a haze-proof filter element; 3. a heat sink; 301. a clip seat; 3011. a cavity; 3012. a partition plate; 3013. a mesopore; 3014. a guide plate; 3015. a hauling rope; 3016. a piston plate; 3017. a spring; 3018. an exhaust hole; 302. bending the pipe; 303. a bellows; 304. an electromagnetic valve; 305. a slide base; 306. a friction block; 307. sucking holes; 308. a rubber bladder; 309. a cleaning brush; 310. a vision sensor; 4. an air conditioning system; 5. a frame plate; 501. a strut; 502. installing a frame; 503. a solar photovoltaic panel; 504. a charge controller; 505. a battery; 506. an inverter; 6. a heat preservation box; 601. a water injection pipe; 602. an electric heater; 603. a water pump; 604. a second temperature sensor; 605. a return pipe; 7. a municipal power supply module; 8. a single chip controller; 9. and a climate monitoring module.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The first embodiment:

referring to fig. 1-4, the present embodiment provides a technical solution: the utility model provides a low carbon environment-friendly intelligence house equipment, includes heat preservation energy storage component, air conditioning system 4, installs in the inside wall 2 in house, locates the outside solar PV modules in house and locates the communication control subassembly in the house outside, and the side of cutting off 2 is equipped with heat preservation door 201, cuts off 2 top surface both sides and is equipped with louver 202 and window 203 that adjusts the temperature respectively, and louver 202 is embedded to have and prevents haze filter core 206.

Specifically, louver 202 is used for cutting off 2 insides and takes a breath with the external world, prevents that haze filter core 206 can prevent that the haze from getting into the inside of cutting off 2 when haze day, and window 203 that adjusts the temperature that can adjust when cutting off 2 inside high temperatures cuts off 2 inside, and air conditioning system 4 is used for cutting off 2 insides and cooling down including locating the air conditioner internal unit that cuts off 2 inner walls and the air conditioner outer machine outside locating the house 4, air conditioning system 4.

An insulating layer 205 is arranged between the inner wall and the outer wall of the partition 2, and the insulating layer 205 is made of rubber plastic foam boards, polyurethane, extrusion molding core boards, PVC, STP and VIP insulating materials.

Specifically, the insulating layer 205 keeps the inside of the partition 2 in a state close to heat insulation, and blocks heat exchange between the inside of the partition 2 and the outside.

The solar photovoltaic module comprises a frame plate 5 arranged on the outer side of a house, a charging controller 504 and an inverter 506, a supporting rod 501 is arranged at the end of the frame plate 5, an installation frame 502 is arranged on the top end of the supporting rod 501, a solar photovoltaic plate 503 is arranged inside the installation frame 502, a storage battery 505 is arranged on the surface of the frame plate 5, the output end of the solar photovoltaic plate 503 is electrically connected with the input end of the charging controller 504, the output end of the charging controller 504 is electrically connected with the input end of the storage battery 505, the output end of the storage battery 505 is electrically connected with the input end of the inverter 506, and the output end of the inverter 506 is electrically connected with the input end of the single chip microcomputer controller 8.

Specifically, the solar photovoltaic module converts solar energy into electric energy to be stored in the storage battery 505 for supplying power to each electrical element.

The heat preservation energy storage assembly comprises a heat preservation box 6 arranged outside a house, a return pipe 605 is arranged on the top surface of the heat preservation box 6, the return pipe 605 is communicated with an output pipe of the radiator 3, a water pump 603 is arranged on the top surface of the heat preservation box 6, an input port of the water pump 603 is communicated with the heat preservation box 6, an output port of the water pump 603 is communicated with an input pipe of the radiator 3 through a guide pipe, a water injection pipe 601 is arranged on the top surface of the heat preservation box 6, a second temperature sensor 604 is arranged on the side surface of the heat preservation box 6, an electric heater 602 is arranged on the top surface of the heat preservation box 6, the output end of the single chip microcomputer controller 8 is electrically connected with the electric heater 602 and the input end of the water pump 603 respectively, and the single chip microcomputer controller 8 is electrically connected with the second temperature sensor 604 in a bidirectional mode.

Specifically, the heat preservation energy storage assembly is used for recovering and storing redundant heat emitted by a human body, so that the internal temperature of the partition 2 can be supplemented when the internal temperature of the partition 2 is reduced, and the heat preservation box 6 is filled with an antifreezing solution.

The inboard of wall 2 is equipped with the heat recovery subassembly, the heat recovery subassembly with heat preservation and the cooperation of heat preservation energy storage subassembly are realized wall 2 is in winter self-heating, and the heat recovery subassembly is including locating the radiator 3 that cuts off 2 inner walls.

Specifically, the heat recovery assembly can utilize the radiator 3 to exchange heat with the inside of the partition 2, when the temperature inside the partition 2 exceeds a set value, the low-temperature antifreeze in the radiator 3 can be used for absorbing the high temperature inside the partition 2, meanwhile, the temperature of the antifreeze is increased, and the warmed antifreeze is stored in the heat-preservation energy storage assembly, so that the heat recovery inside the partition 2 can be realized.

A first temperature sensor 204 is arranged on the inner side of the partition 2, and the first temperature sensor 204 is in bidirectional electric connection with the single-chip microcomputer controller 8.

Specifically, the first temperature sensor 204 is configured to monitor a temperature value inside the partition 2 in real time, so as to adjust the temperature inside the partition 2 in time.

The communication control assembly comprises a municipal power supply module 7 arranged on the outer side of the house, a single-chip microcomputer controller 8, a climate monitoring module 9 and a wireless communication module 1, the output end of the municipal power supply module 7 is electrically connected with the input end of the single-chip microcomputer controller 8, the single-chip microcomputer controller 8 is electrically connected with the wireless communication module 1 in a two-way mode, and the output end of the single-chip microcomputer controller 8 is electrically connected with the input end of the air conditioning system 4.

Specifically, municipal power supply module 7 can carry out timely replenishment to the power consumption of each load when solar energy generated energy is not enough, single chip microcomputer controller 8 is through the work of each electric element of the program control that has compiled in advance, simultaneously, temperature information and external climate information transmission that first temperature sensor 204, second temperature sensor 604 and climate monitoring module 9 will be monitored transmit for single chip microcomputer controller 8, single chip microcomputer controller 8 carries out the data interaction through wireless communication module 1 and terminal after carrying out the analysis arrangement with the received information data, thereby can be convenient carry out real-time supervision and regulation to the temperature in cutting off 2 on other mobile terminals such as cell-phone, computer.

The climate monitoring module 9 is in bidirectional electric connection with the singlechip controller 8.

Specifically, the climate monitoring module 9 is configured to monitor changes of the outside climate, including seasonal changes, changes of air temperature, and atmospheric pollution conditions.

This embodiment device is when using, climate monitoring module 9 discerns when the current season is summer, because cut off the effect of insulating layer 205 in 2, reduce the heat exchange between 2 inside and the external world of cutting off by a wide margin, then effectively block external high-temperature gas and get into and cut off 2 inside, the high temperature has been avoided appearing in 2 insides of cutting off, utilize air conditioning system 4 to cool down 2 inside of cutting off this moment, because cut off 2 inside temperature for the external temperature relatively lower, utilize air conditioning system 4 through with lie in the air conditioner indoor unit cooperation that cuts off 2 can be very light with the temperature drop, therefore air conditioning system 4's load reduces by a wide margin, can effectively reduce air conditioning system 4's power consumption, thereby reduce carbon emission.

In addition, when the climate monitoring module 9 recognizes that the current season is spring or autumn, because the weather is cool, at this time, only the ventilation window 202 and the thermal insulation door 201 need to be opened, so as to realize the circulation of air inside the partition 2, the inside of the partition 2 can be kept consistent with the outside temperature, when the climate monitoring module 9 detects that the pollution index of the outside atmosphere exceeds a set value, the ventilation window 202 and the thermal insulation door 201 are closed, the temperature adjusting window 203 is started, the exhaust fan inside the temperature adjusting window 203 is used for exhausting the outside, meanwhile, the outside air enters the partition 2 through the ventilation window 202 and the haze-proof filter element 206, the haze-proof filter element 206 filters pollutants in the atmosphere, so as to realize the purification of the air entering the partition 2, meanwhile, the outside air can still be kept consistent with the temperature inside the partition 2, and, in spring and autumn, because the temperature is low at night, the temperature inside the partition 2 is low at this time, the rotating speed of the exhaust fan in the temperature adjusting window 203 can be reduced, further, the ventilation volume is reduced, and the temperature loss in the partition 2 is prevented, and in spring and in autumn, the midday, the air conditioning temperature is still higher, the cooling system 4 can be used.

In addition, when the climate monitoring module 9 recognizes that the current season is in winter, the ventilation window 202 and the thermal insulation door 201 are still in a closed state, and heat exchange between outside cold air and the inside of the partition 2 is effectively blocked under the action of the thermal insulation layer 205, meanwhile, a person located inside the partition 2 acts as a heat source, so that the temperature inside the partition 2 is gradually increased, thereby realizing self-heating inside the partition 2, however, when the temperature inside the partition 2 is continuously increased and the temperature inside the partition 2 detected by the first temperature sensor 204 is higher than the first threshold value set by the first temperature sensor 204, the temperature inside the partition 2 already affects the comfort level of the person, at this time, the first temperature sensor 204 feeds back a signal to the single chip microcomputer controller 8, the water pump 603 is automatically started through a pre-programmed control program, the low-temperature antifreeze solution in the thermal insulation box 6 is pumped out to be sent into the radiator 3 through the input pipe on the radiator 3, finally, the antifreeze flows back into the insulation can 6 through an output pipe and a return pipe 605 on the radiator 3, when the antifreeze flows through the radiator 3, the antifreeze can absorb redundant heat emitted by a human body in the partition 2 when passing through the radiator 3 by utilizing the good heat conductivity of the radiator 3, and simultaneously, the temperature of the antifreeze is increased, so that when the antifreeze flows back into the insulation can 6, the temperature can be stored by utilizing the good heat insulation performance of the insulation can 6, and the temperature inside the partition 2 is reduced, however, when the second temperature sensor 604 detects that the temperature of the antifreeze in the insulation can 6 reaches the first threshold value set by the second temperature sensor 604 and keeps unchanged, the heat storage amount of the antifreeze reaches the limit, but when the first temperature sensor 204 detects that the temperature in the partition 2 is still larger than the first threshold value set by the first temperature sensor 204 and continues to rise, the first temperature sensor 204 and the second temperature sensor 604 transmit signals to the single chip microcomputer controller 8, and the exhaust fan in the temperature adjusting window 203 is started to realize ventilation and heat dissipation inside the partition 2, so that redundant heat inside the partition 2 is exhausted, and the temperature inside the partition 2 is reduced.

In addition, when the number of people inside the partition 2 decreases, the number of heat sources inside the partition 2 decreases at this time, the heat generated by the human body heat source is not enough to maintain the temperature inside the partition 2 at this time, so that the temperature inside the partition 2 decreases, when the first temperature sensor 204 detects that the temperature inside the partition 2 decreases to the second threshold set by the first temperature sensor 204, and the first threshold is greater than the second threshold, the water pump 603 is started, the antifreeze liquid with relatively high temperature stored in the heat preservation box 6 is pumped out and sent into the radiator 3, the antifreeze liquid with high temperature exchanges heat with the air inside the partition 2, so that the temperature inside the partition 2 increases, when the second temperature sensor 604 detects that the temperature inside the heat preservation box 6 decreases to the second threshold set by the second temperature sensor 604, and the second threshold is less than the first threshold, which indicates that all the heat of the antifreeze liquid stored in the heat preservation box 6 is released, the second temperature sensor 604 feeds a signal back to the controller 8, the storage battery 505 is started, the electric energy is supplied to the electric heater 602 inside the heat preservation box 6 by the solar photovoltaic panel 503 stored in the storage battery 505, and the electric energy supplied to the municipal heat storage module 602, so that the antifreeze liquid stored in the heat storage module 602 reaches the municipal administration module 602, and the municipal administration module can be used for heating the antifreeze liquid, so that the antifreeze liquid stored in the storage battery module 602, and the storage module 602 can be used for heating the municipal administration module 7.

Second embodiment:

referring to fig. 5-8, based on the first embodiment, in the practical use process, since the heat sink 3 is used only in winter, the heat sink 3 may be idle for a long time before winter, and during the idle process of the heat sink 3, the outer side of the heat sink 3 may be covered with dust impurities and relatively tightly adhered stains, and during the use process of the heat sink 3, the antifreeze inside the heat sink 3 may be prevented from exchanging heat with the inside of the partition 2, thereby affecting the efficiency of temperature adjustment inside the partition 2, furthermore, due to the long-time idle, the outer surface of the heat sink 3 is easily oxidized and rusted, and if the antifreeze is not removed in time, the rusting of the outer surface of the heat sink 3 may be accelerated, thereby shortening the service life of the heat sink 3, in order to solve the above problems:

the heat radiator 3 is sleeved with the clip seat 301, cavities 3011 are formed in two sides of the clip seat 301, a partition 3012 is arranged on the upper side of the cavity 3011, a middle hole 3013 is formed in the middle of the partition 3012, guide plates 3014 are arranged at two ends of the upper side of the partition 3012 in the cavity 3011, a traction rope 3015 penetrates through the middle of the guide plate 3014, one end, far away from the middle hole 3013, of the traction rope 3015 penetrates through the top of the cavity 3011 and is fixedly connected with the top of the heat radiator 3, piston plates 3016 are symmetrically and slidably matched with two sides of the middle hole 3013 in the middle of the partition 3012, the other end of the traction rope 3015 is fixedly connected with the middle of the piston plate 3016, a spring 3017 is sleeved on the traction rope 3015 between the guide plate 3014 and the piston plate 3016, and exhaust holes 3018 are formed in the end portions of the clip seat 301 and the piston plate 3016.

Specifically, when the clip 301 moves downward, the pulling ropes 3015 on both sides respectively drive the piston plates 3016 on both sides to slide away from each other, and the spring 3017 is compressed, so that air can be sucked through the middle hole 3013, and the space in the cavity 3011 at the bottom of the partition 3012 is in a negative pressure state, so that external dust and impurities are sucked into the cavity 3011 through the suction holes 307 formed in the slider 305.

The back side of the top of the radiator 3 is provided with an elbow 302, the bottom end of the elbow 302 is connected with a corrugated pipe 303, specifically, the up-and-down movement of the clip seat 301 is realized by utilizing the scalability of the corrugated pipe 303, the bottom end of the corrugated pipe 303 is fixedly connected with the top surface of the clip seat 301, the elbow 302 is provided with an electromagnetic valve 304, the bottoms of two opposite inner side surfaces of the clip seat 301 are correspondingly provided with a through groove communicated with the cavity 3011, the through groove is internally matched with a sliding seat 305 in a sliding way, the opposite side surfaces of the two sliding seats 305 are both provided with friction blocks 306, specifically, the roughness of the opposite side of the friction blocks 306 at the two sides is higher, thereby the dirt and the rust which are closely attached to the outer side of the radiator 3 can be erased by utilizing the friction force, suction hole 307 has been seted up to the side of slide 305 evenly running through, one side that slide 305 is located cavity 3011 is equipped with the rubber bag 308 with cavity 3011 inner wall fixed connection, it is specific, rubber bag 308 intussuseption is filled with the gas that the coefficient of thermal expansion and contraction is high, thereby usable radiator 3 temperature's rising realizes the inflation of rubber bag 308, thereby release clutch blocks 306, the top of two relative medial surfaces of returning shape seat 301 corresponds and is equipped with cleaning brush 309, the position that the inner wall of wall 2 corresponds with the dorsal part of radiator 3 is equipped with vision sensor 310, vision sensor 310 is connected with single chip microcomputer controller 8 both-way electricity, it is specific, vision sensor 310 is used for monitoring the cleanliness and the corrosion condition of radiator 3 surface.

When the device of the embodiment is used, in the process of recovering and storing energy by using the heat radiator 3 to surplus heat emitted by a human body, at this time, the temperature of the antifreeze is low, so that the rubber bag 308 contracts, at this time, the friction block 306 does not work, the antifreeze circularly flows in the heat radiator 3, when the vision sensor 310 monitors that the outer surface of the heat radiator 3 is covered with more dust impurities, the electromagnetic valve 304 is switched on, and simultaneously the water pump 603 performs positive and negative work, namely, the water pump 603 enters a suction alternating working state, in the process of pumping the antifreeze out of the insulation can 6 by the water pump 603, part of the antifreeze is discharged from the elbow 302 on the side surface of the top of the heat radiator 3, because the connection part between the corrugated pipe 303 and the top surface of the clip 301 is in a closed state, and the corrugated pipe 303 has a telescopic function, the high pressure of the antifreeze can push the clip 301 downwards to slide, the corrugated pipe 303 extends, in the process of suck back by the water pump 603, the corrugated pipe 303 contracts and resets, so that the upper and lower reciprocating motion of the clip of the outer surface of the heat radiator 3 is realized, in the clip of the dust in the heat radiator 3, and the dust impurities in the heat radiator 2 are prevented from being removed by the heat exchanger of the heat radiator.

However, in the process of cleaning the outer surface of the heat sink 3 by the up-and-down reciprocating motion of the clip 301, a lot of dust and impurities may be scattered in the air inside the partition 2, which affects the air quality inside the partition 2, and in order to solve this problem, one end of the pulling rope 3015 is fixed to the top of the heat sink 3, and the other end of the pulling rope 3015 is connected to the piston plate 3016 slidably fitted on the partition 3012, so that when the clip 301 moves downward, the pulling rope 3015 on both sides respectively pull the piston plates 3016 on both sides to move backward, at this time, the spring 3017 is compressed, and then the cavity 3011 at the bottom of the partition 3012 is in a negative pressure state through the middle hole 3013, therefore, when the outer surface of the heat sink 3 is cleaned by the cleaning brush 309, the cleaned dust and impurities are sucked into the cavity 3011 at the bottom of the partition 3012 through the suction hole 307, so that the cleaned dust and impurities can be recovered, and the dust and impurities are prevented from being scattered in the air inside the partition 2 to affect the air quality inside the partition 2.

In addition, in the process of releasing the heat stored in the insulation can 6 into the partition 2, at this time, the antifreeze solution with a higher temperature circularly flows in the radiator 3, the heat in the antifreeze solution is released into the partition 2 through heat exchange, at this time, the vision sensor 310 is started, when the vision sensor 310 monitors that stains and rusts are still closely attached to the outer surface of the radiator 3, the water pump 603 is made to be in a suction alternating working state again to enable the square-shaped seat 301 to reciprocate up and down, and meanwhile, the rubber bag 308 absorbs the heat in the antifreeze solution to expand and pushes the sliding seat 305 to slide, so that the friction block 306 extends out, further, in the process of reciprocating up and down of the square-shaped seat 301, the stains and rusts closely attached to the outer side of the radiator 3 are erased through the adhesion of the friction block 306 and the outer surface of the radiator 3, further cleaning and rust removal outside the radiator 3 are realized, further heat exchange is prevented from being influenced, further diffusion of rusts is avoided, so that the service life of the radiator 3 is influenced, and further, the piston plate 3015 is driven to slide through the suction hole 3016, dust in the cavity is prevented from being sucked into the dust collection of the dust, and dust is prevented from floating in the cavity 3012.

In conclusion, the invention can remove dust and impurities and stains with strong adhesiveness on the outer side of the radiator 3, prevent the dust and impurities and the stains from influencing the antifreeze in the radiator 3 to exchange heat with the inner part of the partition 2, and effectively slow down further oxidation corrosion on the outer side of the radiator 3 and prolong the service life by removing the rust adhered on the outer side of the radiator 3.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes performed by the present specification and drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (10)

1. A low-carbon environment-friendly intelligent household device is characterized by comprising a heat-insulation energy-storage assembly, an air-conditioning system, a partition wall arranged inside a house, a solar photovoltaic assembly arranged outside the house and a communication control assembly arranged outside the house, wherein a heat-insulation door is arranged on the side surface of the partition wall;

a ventilation window and a temperature adjusting window are respectively arranged on two sides of the top surface of the partition, and an anti-haze filter element is embedded in the ventilation window;

be equipped with the heat preservation between the inner wall and the outer wall of wall, the inboard of wall is equipped with the heat recovery subassembly, the heat recovery subassembly is including the radiator of locating the wall inner wall, the heat recovery subassembly with heat preservation and heat preservation energy storage subassembly cooperation are realized the wall is at winter self-heating.

2. The low-carbon environment-friendly intelligent household equipment as claimed in claim 1, wherein: the communication control assembly comprises a municipal power supply module, a single-chip microcomputer controller, a climate monitoring module and a wireless communication module, wherein the municipal power supply module, the single-chip microcomputer controller, the climate monitoring module and the wireless communication module are arranged on the outer side of the house, the output end of the municipal power supply module is electrically connected with the input end of the single-chip microcomputer controller, the single-chip microcomputer controller is electrically connected with the wireless communication module in a two-way mode, the output end of the single-chip microcomputer controller is electrically connected with the input end of the air conditioning system, and the climate monitoring module is electrically connected with the single-chip microcomputer controller in a two-way mode.

3. The low-carbon environment-friendly intelligent household equipment as claimed in claim 2, wherein: solar PV modules is including locating frame plate, charge controller and the dc-to-ac converter in the house outside, the tip of frame plate is equipped with branch, the top of branch is equipped with the installing frame, the inside of installing frame is provided with the solar photovoltaic board, the surface of frame plate is equipped with the battery, the output of solar photovoltaic board with charge controller's input electricity is connected, charge controller's output with the input electricity of battery is connected, the output of battery with the input electricity of dc-to-ac converter is connected, the output of dc-to-ac converter with single chip microcomputer controller's input electricity is connected.

4. The low-carbon environment-friendly intelligent household equipment as claimed in claim 3, wherein: the heat recovery assembly comprises a radiator arranged on the inner wall of the partition, and the air conditioning system comprises an air conditioner internal unit arranged on the inner wall of the partition and an air conditioner external unit arranged on the outer side of the house.

5. The low-carbon environment-friendly intelligent household equipment as claimed in claim 4, wherein: the heat preservation energy storage assembly comprises a heat preservation box arranged outside a house, a return pipe is arranged on the top surface of the heat preservation box and communicated with an output pipe of the radiator, a water pump is arranged on the top surface of the heat preservation box, an input port of the water pump is communicated with the heat preservation box, an output port of the water pump is communicated with an input pipe of the radiator through a guide pipe, and an input end of the water pump is electrically connected with an output end of the single chip microcomputer controller.

6. The low-carbon environment-friendly intelligent household equipment as claimed in claim 5, wherein: the radiator is connected with a return seat in a sleeved mode, cavities are formed in the two sides of the return seat, a partition plate is arranged on the upper side of each cavity, a middle hole is formed in the middle of the partition plate, guide plates are arranged at the two ends of the upper side of the partition plate in the cavity, a traction rope penetrates through the middle of each guide plate, one end, far away from the middle hole, of each traction rope penetrates through the top of the cavity and the top of the radiator, the middle of each partition plate is located on a piston plate in a sliding fit mode in the bilateral symmetry of the middle hole, the other end of each traction rope is fixedly connected with the middle of the piston plate, a spring is connected between each guide plate and the corresponding piston plate in a sleeved mode in the position of each traction rope, and exhaust holes are formed in the end portions of the return seat and the positions corresponding to the piston plates.

7. The low-carbon environment-friendly intelligent household equipment as claimed in claim 6, wherein: the top dorsal part of radiator is equipped with the return bend, the bottom of return bend is connected with the bellows, the bottom of bellows and the top surface fixed connection who returns the shape seat, be equipped with the solenoid valve on the return bend, the bottom correspondence of two relative medial surfaces of returning the shape seat sets up the logical groove with the cavity intercommunication, it has the slide, two to lead to sliding fit in the groove the opposite flank of slide all is equipped with the clutch blocks, the side of slide evenly runs through has seted up and has inhaled the hole, one side that the slide is located the cavity is equipped with the rubber bag with cavity inner wall fixed connection, the top correspondence of two relative medial surfaces of returning the shape seat is equipped with the cleaning brush, the inner wall that cuts off is equipped with the vision sensor with the position that the dorsal part of radiator corresponds, vision sensor and single chip microcomputer controller both-way electricity are connected.

8. The low-carbon environment-friendly intelligent household equipment as claimed in claim 5, wherein: the top surface of insulation can is equipped with the water injection pipe, the side of insulation can is equipped with second temperature sensor, the top surface of insulation can is equipped with the electric heater, single chip microcomputer controller's output with the input electricity of electric heater is connected, single chip microcomputer controller and the two-way electricity of second temperature sensor are connected.

9. The low-carbon environment-friendly intelligent household equipment as claimed in claim 2, wherein: and a first temperature sensor is arranged on the inner side of the partition and is electrically connected with the single chip microcomputer controller in a bidirectional mode.

10. The low-carbon environment-friendly intelligent household equipment as claimed in claim 1, wherein: the heat preservation layer is made of rubber and plastic foam boards, polyurethane, extrusion molding core boards, PVC, STP and VIP heat preservation materials.

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